modules/audio_processing/beamformer/nonlinear_beamformer.cc - src.git - Git at Google

 /*
  *  Copyright (c) 2014 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #define _USE_MATH_DEFINES

 #include "modules/audio_processing/beamformer/nonlinear_beamformer.h"

 #include <algorithm>
 #include <cmath>
 #include <numeric>
 #include <vector>

 #include "common_audio/window_generator.h"
 #include "modules/audio_processing/beamformer/covariance_matrix_generator.h"
 #include "rtc_base/arraysize.h"

 namespace webrtc {
 namespace {

 // Alpha for the Kaiser Bessel Derived window.
 const float kKbdAlpha = 1.5f;

 const float kSpeedOfSoundMeterSeconds = 343;

 // The minimum separation in radians between the target direction and an
 // interferer scenario.
 const float kMinAwayRadians = 0.2f;

 // The separation between the target direction and the closest interferer
 // scenario is proportional to this constant.
 const float kAwaySlope = 0.008f;

 // When calculating the interference covariance matrix, this is the weight for
 // the weighted average between the uniform covariance matrix and the angled
 // covariance matrix.
 // Rpsi = Rpsi_angled * kBalance + Rpsi_uniform * (1 - kBalance)
 const float kBalance = 0.95f;

 // Alpha coefficients for mask smoothing.
 const float kMaskTimeSmoothAlpha = 0.2f;
 const float kMaskFrequencySmoothAlpha = 0.6f;

 // The average mask is computed from masks in this mid-frequency range. If these
 // ranges are changed |kMaskQuantile| might need to be adjusted.
 const int kLowMeanStartHz = 200;
 const int kLowMeanEndHz = 400;

 // Range limiter for subtractive terms in the nominator and denominator of the
 // postfilter expression. It handles the scenario mismatch between the true and
 // model sources (target and interference).
 const float kCutOffConstant = 0.9999f;

 // Quantile of mask values which is used to estimate target presence.
 const float kMaskQuantile = 0.7f;
 // Mask threshold over which the data is considered signal and not interference.
 // It has to be updated every time the postfilter calculation is changed
 // significantly.
 // TODO(aluebs): Write a tool to tune the target threshold automatically based
 // on files annotated with target and interference ground truth.
 const float kMaskTargetThreshold = 0.01f;
 // Time in seconds after which the data is considered interference if the mask
 // does not pass |kMaskTargetThreshold|.
 const float kHoldTargetSeconds = 0.25f;

 // To compensate for the attenuation this algorithm introduces to the target
 // signal. It was estimated empirically from a low-noise low-reverberation
 // recording from broadside.
 const float kCompensationGain = 2.f;

 // Does conjugate(|norm_mat|) * |mat| * transpose(|norm_mat|). No extra space is
 // used; to accomplish this, we compute both multiplications in the same loop.
 // The returned norm is clamped to be non-negative.
 float Norm(const ComplexMatrix<float>& mat,
            const ComplexMatrix<float>& norm_mat) {
   RTC_CHECK_EQ(1, norm_mat.num_rows());
   RTC_CHECK_EQ(norm_mat.num_columns(), mat.num_rows());
   RTC_CHECK_EQ(norm_mat.num_columns(), mat.num_columns());

   complex<float> first_product = complex<float>(0.f, 0.f);
   complex<float> second_product = complex<float>(0.f, 0.f);

   const complex<float>* const* mat_els = mat.elements();
   const complex<float>* const* norm_mat_els = norm_mat.elements();

   for (size_t i = 0; i < norm_mat.num_columns(); ++i) {
     for (size_t j = 0; j < norm_mat.num_columns(); ++j) {
       first_product += conj(norm_mat_els[0][j]) * mat_els[j][i];
     }
     second_product += first_product * norm_mat_els[0][i];
     first_product = 0.f;
   }
   return std::max(second_product.real(), 0.f);
 }

 // Does conjugate(|lhs|) * |rhs| for row vectors |lhs| and |rhs|.
 complex<float> ConjugateDotProduct(const ComplexMatrix<float>& lhs,
                                    const ComplexMatrix<float>& rhs) {
   RTC_CHECK_EQ(1, lhs.num_rows());
   RTC_CHECK_EQ(1, rhs.num_rows());
   RTC_CHECK_EQ(lhs.num_columns(), rhs.num_columns());

   const complex<float>* const* lhs_elements = lhs.elements();
   const complex<float>* const* rhs_elements = rhs.elements();

   complex<float> result = complex<float>(0.f, 0.f);
   for (size_t i = 0; i < lhs.num_columns(); ++i) {
     result += conj(lhs_elements[0][i]) * rhs_elements[0][i];
   }

   return result;
 }

 // Works for positive numbers only.
 size_t Round(float x) {
   return static_cast<size_t>(std::floor(x + 0.5f));
 }

 // Calculates the sum of squares of a complex matrix.
 float SumSquares(const ComplexMatrix<float>& mat) {
   float sum_squares = 0.f;
   const complex<float>* const* mat_els = mat.elements();
   for (size_t i = 0; i < mat.num_rows(); ++i) {
     for (size_t j = 0; j < mat.num_columns(); ++j) {
       float abs_value = std::abs(mat_els[i][j]);
       sum_squares += abs_value * abs_value;
     }
   }
   return sum_squares;
 }

 // Does |out| = |in|.' * conj(|in|) for row vector |in|.
 void TransposedConjugatedProduct(const ComplexMatrix<float>& in,
                                  ComplexMatrix<float>* out) {
   RTC_CHECK_EQ(1, in.num_rows());
   RTC_CHECK_EQ(out->num_rows(), in.num_columns());
   RTC_CHECK_EQ(out->num_columns(), in.num_columns());
   const complex<float>* in_elements = in.elements()[0];
   complex<float>* const* out_elements = out->elements();
   for (size_t i = 0; i < out->num_rows(); ++i) {
     for (size_t j = 0; j < out->num_columns(); ++j) {
       out_elements[i][j] = in_elements[i] * conj(in_elements[j]);
     }
   }
 }

 std::vector<Point> GetCenteredArray(std::vector<Point> array_geometry) {
   for (size_t dim = 0; dim < 3; ++dim) {
     float center = 0.f;
     for (size_t i = 0; i < array_geometry.size(); ++i) {
       center += array_geometry[i].c[dim];
     }
     center /= array_geometry.size();
     for (size_t i = 0; i < array_geometry.size(); ++i) {
       array_geometry[i].c[dim] -= center;
     }
   }
   return array_geometry;
 }

 }  // namespace

 const float NonlinearBeamformer::kHalfBeamWidthRadians = DegreesToRadians(20.f);

 // static
 const size_t NonlinearBeamformer::kNumFreqBins;

 PostFilterTransform::PostFilterTransform(size_t num_channels,
                                          size_t chunk_length,
                                          float* window,
                                          size_t fft_size)
     : transform_(num_channels,
                  num_channels,
                  chunk_length,
                  window,
                  fft_size,
                  fft_size / 2,
                  this),
       num_freq_bins_(fft_size / 2 + 1) {}

 void PostFilterTransform::ProcessChunk(float* const* data, float* final_mask) {
   final_mask_ = final_mask;
   transform_.ProcessChunk(data, data);
 }

 void PostFilterTransform::ProcessAudioBlock(const complex<float>* const* input,
                                             size_t num_input_channels,
                                             size_t num_freq_bins,
                                             size_t num_output_channels,
                                             complex<float>* const* output) {
   RTC_DCHECK_EQ(num_freq_bins_, num_freq_bins);
   RTC_DCHECK_EQ(num_input_channels, num_output_channels);

   for (size_t ch = 0; ch < num_input_channels; ++ch) {
     for (size_t f_ix = 0; f_ix < num_freq_bins_; ++f_ix) {
       output[ch][f_ix] =
           kCompensationGain * final_mask_[f_ix] * input[ch][f_ix];
     }
   }
 }

 NonlinearBeamformer::NonlinearBeamformer(
     const std::vector<Point>& array_geometry,
     size_t num_postfilter_channels,
     SphericalPointf target_direction)
     : num_input_channels_(array_geometry.size()),
       num_postfilter_channels_(num_postfilter_channels),
       array_geometry_(GetCenteredArray(array_geometry)),
       array_normal_(GetArrayNormalIfExists(array_geometry)),
       min_mic_spacing_(GetMinimumSpacing(array_geometry)),
       target_angle_radians_(target_direction.azimuth()),
       away_radians_(std::min(
           static_cast<float>(M_PI),
           std::max(kMinAwayRadians,
                    kAwaySlope * static_cast<float>(M_PI) / min_mic_spacing_))) {
   WindowGenerator::KaiserBesselDerived(kKbdAlpha, kFftSize, window_);
 }

 NonlinearBeamformer::~NonlinearBeamformer() = default;

 void NonlinearBeamformer::Initialize(int chunk_size_ms, int sample_rate_hz) {
   chunk_length_ =
       static_cast<size_t>(sample_rate_hz / (1000.f / chunk_size_ms));
   sample_rate_hz_ = sample_rate_hz;

   high_pass_postfilter_mask_ = 1.f;
   is_target_present_ = false;
   hold_target_blocks_ = kHoldTargetSeconds * 2 * sample_rate_hz / kFftSize;
   interference_blocks_count_ = hold_target_blocks_;

   process_transform_.reset(new LappedTransform(num_input_channels_,
                                                0u,
                                                chunk_length_,
                                                window_,
                                                kFftSize,
                                                kFftSize / 2,
                                                this));
   postfilter_transform_.reset(new PostFilterTransform(
       num_postfilter_channels_, chunk_length_, window_, kFftSize));
   const float wave_number_step =
       (2.f * M_PI * sample_rate_hz_) / (kFftSize * kSpeedOfSoundMeterSeconds);
   for (size_t i = 0; i < kNumFreqBins; ++i) {
     time_smooth_mask_[i] = 1.f;
     final_mask_[i] = 1.f;
     wave_numbers_[i] = i * wave_number_step;
   }

   InitLowFrequencyCorrectionRanges();
   InitDiffuseCovMats();
   AimAt(SphericalPointf(target_angle_radians_, 0.f, 1.f));
 }

 // These bin indexes determine the regions over which a mean is taken. This is
 // applied as a constant value over the adjacent end "frequency correction"
 // regions.
 //
 //             low_mean_start_bin_     high_mean_start_bin_
 //                   v                         v              constant
 // |----------------|--------|----------------|-------|----------------|
 //   constant               ^                        ^
 //             low_mean_end_bin_       high_mean_end_bin_
 //
 void NonlinearBeamformer::InitLowFrequencyCorrectionRanges() {
   low_mean_start_bin_ = Round(static_cast<float>(kLowMeanStartHz) *
                                   kFftSize / sample_rate_hz_);
   low_mean_end_bin_ = Round(static_cast<float>(kLowMeanEndHz) *
                                   kFftSize / sample_rate_hz_);

   RTC_DCHECK_GT(low_mean_start_bin_, 0U);
   RTC_DCHECK_LT(low_mean_start_bin_, low_mean_end_bin_);
 }

 void NonlinearBeamformer::InitHighFrequencyCorrectionRanges() {
   const float kAliasingFreqHz =
       kSpeedOfSoundMeterSeconds /
       (min_mic_spacing_ * (1.f + std::abs(std::cos(target_angle_radians_))));
   const float kHighMeanStartHz = std::min(0.5f *  kAliasingFreqHz,
                                           sample_rate_hz_ / 2.f);
   const float kHighMeanEndHz = std::min(0.75f *  kAliasingFreqHz,
                                         sample_rate_hz_ / 2.f);
   high_mean_start_bin_ = Round(kHighMeanStartHz * kFftSize / sample_rate_hz_);
   high_mean_end_bin_ = Round(kHighMeanEndHz * kFftSize / sample_rate_hz_);

   RTC_DCHECK_LT(low_mean_end_bin_, high_mean_end_bin_);
   RTC_DCHECK_LT(high_mean_start_bin_, high_mean_end_bin_);
   RTC_DCHECK_LT(high_mean_end_bin_, kNumFreqBins - 1);
 }

 void NonlinearBeamformer::InitInterfAngles() {
   interf_angles_radians_.clear();
   const Point target_direction = AzimuthToPoint(target_angle_radians_);
   const Point clockwise_interf_direction =
       AzimuthToPoint(target_angle_radians_ - away_radians_);
   if (!array_normal_ ||
       DotProduct(*array_normal_, target_direction) *
               DotProduct(*array_normal_, clockwise_interf_direction) >=
           0.f) {
     // The target and clockwise interferer are in the same half-plane defined
     // by the array.
     interf_angles_radians_.push_back(target_angle_radians_ - away_radians_);
   } else {
     // Otherwise, the interferer will begin reflecting back at the target.
     // Instead rotate it away 180 degrees.
     interf_angles_radians_.push_back(target_angle_radians_ - away_radians_ +
                                      M_PI);
   }
   const Point counterclock_interf_direction =
       AzimuthToPoint(target_angle_radians_ + away_radians_);
   if (!array_normal_ ||
       DotProduct(*array_normal_, target_direction) *
               DotProduct(*array_normal_, counterclock_interf_direction) >=
           0.f) {
     // The target and counter-clockwise interferer are in the same half-plane
     // defined by the array.
     interf_angles_radians_.push_back(target_angle_radians_ + away_radians_);
   } else {
     // Otherwise, the interferer will begin reflecting back at the target.
     // Instead rotate it away 180 degrees.
     interf_angles_radians_.push_back(target_angle_radians_ + away_radians_ -
                                      M_PI);
   }
 }

 void NonlinearBeamformer::InitDelaySumMasks() {
   for (size_t f_ix = 0; f_ix < kNumFreqBins; ++f_ix) {
     delay_sum_masks_[f_ix].Resize(1, num_input_channels_);
     CovarianceMatrixGenerator::PhaseAlignmentMasks(
         f_ix, kFftSize, sample_rate_hz_, kSpeedOfSoundMeterSeconds,
         array_geometry_, target_angle_radians_, &delay_sum_masks_[f_ix]);

     complex_f norm_factor = sqrt(
         ConjugateDotProduct(delay_sum_masks_[f_ix], delay_sum_masks_[f_ix]));
     delay_sum_masks_[f_ix].Scale(1.f / norm_factor);
   }
 }

 void NonlinearBeamformer::InitTargetCovMats() {
   for (size_t i = 0; i < kNumFreqBins; ++i) {
     target_cov_mats_[i].Resize(num_input_channels_, num_input_channels_);
     TransposedConjugatedProduct(delay_sum_masks_[i], &target_cov_mats_[i]);
   }
 }

 void NonlinearBeamformer::InitDiffuseCovMats() {
   for (size_t i = 0; i < kNumFreqBins; ++i) {
     uniform_cov_mat_[i].Resize(num_input_channels_, num_input_channels_);
     CovarianceMatrixGenerator::UniformCovarianceMatrix(
         wave_numbers_[i], array_geometry_, &uniform_cov_mat_[i]);
     complex_f normalization_factor = uniform_cov_mat_[i].elements()[0][0];
     uniform_cov_mat_[i].Scale(1.f / normalization_factor);
     uniform_cov_mat_[i].Scale(1 - kBalance);
   }
 }

 void NonlinearBeamformer::InitInterfCovMats() {
   for (size_t i = 0; i < kNumFreqBins; ++i) {
     interf_cov_mats_[i].clear();
     for (size_t j = 0; j < interf_angles_radians_.size(); ++j) {
       interf_cov_mats_[i].push_back(std::unique_ptr<ComplexMatrixF>(
           new ComplexMatrixF(num_input_channels_, num_input_channels_)));
       ComplexMatrixF angled_cov_mat(num_input_channels_, num_input_channels_);
       CovarianceMatrixGenerator::AngledCovarianceMatrix(
           kSpeedOfSoundMeterSeconds,
           interf_angles_radians_[j],
           i,
           kFftSize,
           kNumFreqBins,
           sample_rate_hz_,
           array_geometry_,
           &angled_cov_mat);
       // Normalize matrices before averaging them.
       complex_f normalization_factor = angled_cov_mat.elements()[0][0];
       angled_cov_mat.Scale(1.f / normalization_factor);
       // Weighted average of matrices.
       angled_cov_mat.Scale(kBalance);
       interf_cov_mats_[i][j]->Add(uniform_cov_mat_[i], angled_cov_mat);
     }
   }
 }

 void NonlinearBeamformer::NormalizeCovMats() {
   for (size_t i = 0; i < kNumFreqBins; ++i) {
     rxiws_[i] = Norm(target_cov_mats_[i], delay_sum_masks_[i]);
     rpsiws_[i].clear();
     for (size_t j = 0; j < interf_angles_radians_.size(); ++j) {
       rpsiws_[i].push_back(Norm(*interf_cov_mats_[i][j], delay_sum_masks_[i]));
     }
   }
 }

 void NonlinearBeamformer::AnalyzeChunk(const ChannelBuffer<float>& data) {
   RTC_DCHECK_EQ(data.num_channels(), num_input_channels_);
   RTC_DCHECK_EQ(data.num_frames_per_band(), chunk_length_);

   old_high_pass_mask_ = high_pass_postfilter_mask_;
   process_transform_->ProcessChunk(data.channels(0), nullptr);
 }

 void NonlinearBeamformer::PostFilter(ChannelBuffer<float>* data) {
   RTC_DCHECK_EQ(data->num_frames_per_band(), chunk_length_);
   // TODO(aluebs): Change to RTC_CHECK_EQ once the ChannelBuffer is updated.
   RTC_DCHECK_GE(data->num_channels(), num_postfilter_channels_);

   postfilter_transform_->ProcessChunk(data->channels(0), final_mask_);

   // Ramp up/down for smoothing is needed in order to avoid discontinuities in
   // the transitions between 10 ms frames.
   const float ramp_increment =
       (high_pass_postfilter_mask_ - old_high_pass_mask_) /
       data->num_frames_per_band();
   for (size_t i = 1; i < data->num_bands(); ++i) {
     float smoothed_mask = old_high_pass_mask_;
     for (size_t j = 0; j < data->num_frames_per_band(); ++j) {
       smoothed_mask += ramp_increment;
       for (size_t k = 0; k < num_postfilter_channels_; ++k) {
         data->channels(i)[k][j] *= smoothed_mask;
       }
     }
   }
 }

 void NonlinearBeamformer::AimAt(const SphericalPointf& target_direction) {
   target_angle_radians_ = target_direction.azimuth();
   InitHighFrequencyCorrectionRanges();
   InitInterfAngles();
   InitDelaySumMasks();
   InitTargetCovMats();
   InitInterfCovMats();
   NormalizeCovMats();
 }

 bool NonlinearBeamformer::IsInBeam(const SphericalPointf& spherical_point) {
   // If more than half-beamwidth degrees away from the beam's center,
   // you are out of the beam.
   return fabs(spherical_point.azimuth() - target_angle_radians_) <
          kHalfBeamWidthRadians;
 }

 bool NonlinearBeamformer::is_target_present() { return is_target_present_; }

 void NonlinearBeamformer::ProcessAudioBlock(const complex_f* const* input,
                                             size_t num_input_channels,
                                             size_t num_freq_bins,
                                             size_t num_output_channels,
                                             complex_f* const* output) {
   RTC_CHECK_EQ(kNumFreqBins, num_freq_bins);
   RTC_CHECK_EQ(num_input_channels_, num_input_channels);
   RTC_CHECK_EQ(0, num_output_channels);

   // Calculating the post-filter masks. Note that we need two for each
   // frequency bin to account for the positive and negative interferer
   // angle.
   for (size_t i = low_mean_start_bin_; i <= high_mean_end_bin_; ++i) {
     eig_m_.CopyFromColumn(input, i, num_input_channels_);
     float eig_m_norm_factor = std::sqrt(SumSquares(eig_m_));
     if (eig_m_norm_factor != 0.f) {
       eig_m_.Scale(1.f / eig_m_norm_factor);
     }

     float rxim = Norm(target_cov_mats_[i], eig_m_);
     float ratio_rxiw_rxim = 0.f;
     if (rxim > 0.f) {
       ratio_rxiw_rxim = rxiws_[i] / rxim;
     }

     complex_f rmw = abs(ConjugateDotProduct(delay_sum_masks_[i], eig_m_));
     rmw *= rmw;
     float rmw_r = rmw.real();

     new_mask_[i] = CalculatePostfilterMask(*interf_cov_mats_[i][0],
                                            rpsiws_[i][0],
                                            ratio_rxiw_rxim,
                                            rmw_r);
     for (size_t j = 1; j < interf_angles_radians_.size(); ++j) {
       float tmp_mask = CalculatePostfilterMask(*interf_cov_mats_[i][j],
                                                rpsiws_[i][j],
                                                ratio_rxiw_rxim,
                                                rmw_r);
       if (tmp_mask < new_mask_[i]) {
         new_mask_[i] = tmp_mask;
       }
     }
   }

   ApplyMaskTimeSmoothing();
   EstimateTargetPresence();
   ApplyLowFrequencyCorrection();
   ApplyHighFrequencyCorrection();
   ApplyMaskFrequencySmoothing();
 }

 float NonlinearBeamformer::CalculatePostfilterMask(
     const ComplexMatrixF& interf_cov_mat,
     float rpsiw,
     float ratio_rxiw_rxim,
     float rmw_r) {
   float rpsim = Norm(interf_cov_mat, eig_m_);

   float ratio = 0.f;
   if (rpsim > 0.f) {
     ratio = rpsiw / rpsim;
   }

   float numerator = 1.f - kCutOffConstant;
   if (rmw_r > 0.f) {
     numerator = 1.f - std::min(kCutOffConstant, ratio / rmw_r);
   }

   float denominator = 1.f - kCutOffConstant;
   if (ratio_rxiw_rxim > 0.f) {
     denominator = 1.f - std::min(kCutOffConstant, ratio / ratio_rxiw_rxim);
   }

   return numerator / denominator;
 }

 // Smooth new_mask_ into time_smooth_mask_.
 void NonlinearBeamformer::ApplyMaskTimeSmoothing() {
   for (size_t i = low_mean_start_bin_; i <= high_mean_end_bin_; ++i) {
     time_smooth_mask_[i] = kMaskTimeSmoothAlpha * new_mask_[i] +
                            (1 - kMaskTimeSmoothAlpha) * time_smooth_mask_[i];
   }
 }

 // Copy time_smooth_mask_ to final_mask_ and smooth over frequency.
 void NonlinearBeamformer::ApplyMaskFrequencySmoothing() {
   // Smooth over frequency in both directions. The "frequency correction"
   // regions have constant value, but we enter them to smooth over the jump
   // that exists at the boundary. However, this does mean when smoothing "away"
   // from the region that we only need to use the last element.
   //
   // Upward smoothing:
   //   low_mean_start_bin_
   //         v
   // |------|------------|------|
   //       ^------------------>^
   //
   // Downward smoothing:
   //         high_mean_end_bin_
   //                    v
   // |------|------------|------|
   //  ^<------------------^
   std::copy(time_smooth_mask_, time_smooth_mask_ + kNumFreqBins, final_mask_);
   for (size_t i = low_mean_start_bin_; i < kNumFreqBins; ++i) {
     final_mask_[i] = kMaskFrequencySmoothAlpha * final_mask_[i] +
                      (1 - kMaskFrequencySmoothAlpha) * final_mask_[i - 1];
   }
   for (size_t i = high_mean_end_bin_ + 1; i > 0; --i) {
     final_mask_[i - 1] = kMaskFrequencySmoothAlpha * final_mask_[i - 1] +
                          (1 - kMaskFrequencySmoothAlpha) * final_mask_[i];
   }
 }

 // Apply low frequency correction to time_smooth_mask_.
 void NonlinearBeamformer::ApplyLowFrequencyCorrection() {
   const float low_frequency_mask =
       MaskRangeMean(low_mean_start_bin_, low_mean_end_bin_ + 1);
   std::fill(time_smooth_mask_, time_smooth_mask_ + low_mean_start_bin_,
             low_frequency_mask);
 }

 // Apply high frequency correction to time_smooth_mask_. Update
 // high_pass_postfilter_mask_ to use for the high frequency time-domain bands.
 void NonlinearBeamformer::ApplyHighFrequencyCorrection() {
   high_pass_postfilter_mask_ =
       MaskRangeMean(high_mean_start_bin_, high_mean_end_bin_ + 1);
   std::fill(time_smooth_mask_ + high_mean_end_bin_ + 1,
             time_smooth_mask_ + kNumFreqBins, high_pass_postfilter_mask_);
 }

 // Compute mean over the given range of time_smooth_mask_, [first, last).
 float NonlinearBeamformer::MaskRangeMean(size_t first, size_t last) {
   RTC_DCHECK_GT(last, first);
   const float sum = std::accumulate(time_smooth_mask_ + first,
                                     time_smooth_mask_ + last, 0.f);
   return sum / (last - first);
 }

 void NonlinearBeamformer::EstimateTargetPresence() {
   const size_t quantile = static_cast<size_t>(
       (high_mean_end_bin_ - low_mean_start_bin_) * kMaskQuantile +
       low_mean_start_bin_);
   std::nth_element(new_mask_ + low_mean_start_bin_, new_mask_ + quantile,
                    new_mask_ + high_mean_end_bin_ + 1);
   if (new_mask_[quantile] > kMaskTargetThreshold) {
     is_target_present_ = true;
     interference_blocks_count_ = 0;
   } else {
     is_target_present_ = interference_blocks_count_++ < hold_target_blocks_;
   }
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2014 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#define _USE_MATH_DEFINES

	#include "modules/audio_processing/beamformer/nonlinear_beamformer.h"

	#include <algorithm>
	#include <cmath>
	#include <numeric>
	#include <vector>

	#include "common_audio/window_generator.h"
	#include "modules/audio_processing/beamformer/covariance_matrix_generator.h"
	#include "rtc_base/arraysize.h"

	namespace webrtc {
	namespace {

	// Alpha for the Kaiser Bessel Derived window.
	const float kKbdAlpha = 1.5f;

	const float kSpeedOfSoundMeterSeconds = 343;

	// The minimum separation in radians between the target direction and an
	// interferer scenario.
	const float kMinAwayRadians = 0.2f;

	// The separation between the target direction and the closest interferer
	// scenario is proportional to this constant.
	const float kAwaySlope = 0.008f;

	// When calculating the interference covariance matrix, this is the weight for
	// the weighted average between the uniform covariance matrix and the angled
	// covariance matrix.
	// Rpsi = Rpsi_angled * kBalance + Rpsi_uniform * (1 - kBalance)
	const float kBalance = 0.95f;

	// Alpha coefficients for mask smoothing.
	const float kMaskTimeSmoothAlpha = 0.2f;
	const float kMaskFrequencySmoothAlpha = 0.6f;

	// The average mask is computed from masks in this mid-frequency range. If these
	// ranges are changed \|kMaskQuantile\| might need to be adjusted.
	const int kLowMeanStartHz = 200;
	const int kLowMeanEndHz = 400;

	// Range limiter for subtractive terms in the nominator and denominator of the
	// postfilter expression. It handles the scenario mismatch between the true and
	// model sources (target and interference).
	const float kCutOffConstant = 0.9999f;

	// Quantile of mask values which is used to estimate target presence.
	const float kMaskQuantile = 0.7f;
	// Mask threshold over which the data is considered signal and not interference.
	// It has to be updated every time the postfilter calculation is changed
	// significantly.
	// TODO(aluebs): Write a tool to tune the target threshold automatically based
	// on files annotated with target and interference ground truth.
	const float kMaskTargetThreshold = 0.01f;
	// Time in seconds after which the data is considered interference if the mask
	// does not pass \|kMaskTargetThreshold\|.
	const float kHoldTargetSeconds = 0.25f;

	// To compensate for the attenuation this algorithm introduces to the target
	// signal. It was estimated empirically from a low-noise low-reverberation
	// recording from broadside.
	const float kCompensationGain = 2.f;

	// Does conjugate(\|norm_mat\|) * \|mat\| * transpose(\|norm_mat\|). No extra space is
	// used; to accomplish this, we compute both multiplications in the same loop.
	// The returned norm is clamped to be non-negative.
	float Norm(const ComplexMatrix<float>& mat,
	const ComplexMatrix<float>& norm_mat) {
	RTC_CHECK_EQ(1, norm_mat.num_rows());
	RTC_CHECK_EQ(norm_mat.num_columns(), mat.num_rows());
	RTC_CHECK_EQ(norm_mat.num_columns(), mat.num_columns());

	complex<float> first_product = complex<float>(0.f, 0.f);
	complex<float> second_product = complex<float>(0.f, 0.f);

	const complex<float>* const* mat_els = mat.elements();
	const complex<float>* const* norm_mat_els = norm_mat.elements();

	for (size_t i = 0; i < norm_mat.num_columns(); ++i) {
	for (size_t j = 0; j < norm_mat.num_columns(); ++j) {
	first_product += conj(norm_mat_els[0][j]) * mat_els[j][i];
	}
	second_product += first_product * norm_mat_els[0][i];
	first_product = 0.f;
	}
	return std::max(second_product.real(), 0.f);
	}

	// Does conjugate(\|lhs\|) * \|rhs\| for row vectors \|lhs\| and \|rhs\|.
	complex<float> ConjugateDotProduct(const ComplexMatrix<float>& lhs,
	const ComplexMatrix<float>& rhs) {
	RTC_CHECK_EQ(1, lhs.num_rows());
	RTC_CHECK_EQ(1, rhs.num_rows());
	RTC_CHECK_EQ(lhs.num_columns(), rhs.num_columns());

	const complex<float>* const* lhs_elements = lhs.elements();
	const complex<float>* const* rhs_elements = rhs.elements();

	complex<float> result = complex<float>(0.f, 0.f);
	for (size_t i = 0; i < lhs.num_columns(); ++i) {
	result += conj(lhs_elements[0][i]) * rhs_elements[0][i];
	}

	return result;
	}

	// Works for positive numbers only.
	size_t Round(float x) {
	return static_cast<size_t>(std::floor(x + 0.5f));
	}

	// Calculates the sum of squares of a complex matrix.
	float SumSquares(const ComplexMatrix<float>& mat) {
	float sum_squares = 0.f;
	const complex<float>* const* mat_els = mat.elements();
	for (size_t i = 0; i < mat.num_rows(); ++i) {
	for (size_t j = 0; j < mat.num_columns(); ++j) {
	float abs_value = std::abs(mat_els[i][j]);
	sum_squares += abs_value * abs_value;
	}
	}
	return sum_squares;
	}

	// Does \|out\| = \|in\|.' * conj(\|in\|) for row vector \|in\|.
	void TransposedConjugatedProduct(const ComplexMatrix<float>& in,
	ComplexMatrix<float>* out) {
	RTC_CHECK_EQ(1, in.num_rows());
	RTC_CHECK_EQ(out->num_rows(), in.num_columns());
	RTC_CHECK_EQ(out->num_columns(), in.num_columns());
	const complex<float>* in_elements = in.elements()[0];
	complex<float>* const* out_elements = out->elements();
	for (size_t i = 0; i < out->num_rows(); ++i) {
	for (size_t j = 0; j < out->num_columns(); ++j) {
	out_elements[i][j] = in_elements[i] * conj(in_elements[j]);
	}
	}
	}

	std::vector<Point> GetCenteredArray(std::vector<Point> array_geometry) {
	for (size_t dim = 0; dim < 3; ++dim) {
	float center = 0.f;
	for (size_t i = 0; i < array_geometry.size(); ++i) {
	center += array_geometry[i].c[dim];
	}
	center /= array_geometry.size();
	for (size_t i = 0; i < array_geometry.size(); ++i) {
	array_geometry[i].c[dim] -= center;
	}
	}
	return array_geometry;
	}

	} // namespace

	const float NonlinearBeamformer::kHalfBeamWidthRadians = DegreesToRadians(20.f);

	// static
	const size_t NonlinearBeamformer::kNumFreqBins;

	PostFilterTransform::PostFilterTransform(size_t num_channels,
	size_t chunk_length,
	float* window,
	size_t fft_size)
	: transform_(num_channels,
	num_channels,
	chunk_length,
	window,
	fft_size,
	fft_size / 2,
	this),
	num_freq_bins_(fft_size / 2 + 1) {}

	void PostFilterTransform::ProcessChunk(float* const* data, float* final_mask) {
	final_mask_ = final_mask;
	transform_.ProcessChunk(data, data);
	}

	void PostFilterTransform::ProcessAudioBlock(const complex<float>* const* input,
	size_t num_input_channels,
	size_t num_freq_bins,
	size_t num_output_channels,
	complex<float>* const* output) {
	RTC_DCHECK_EQ(num_freq_bins_, num_freq_bins);
	RTC_DCHECK_EQ(num_input_channels, num_output_channels);

	for (size_t ch = 0; ch < num_input_channels; ++ch) {
	for (size_t f_ix = 0; f_ix < num_freq_bins_; ++f_ix) {
	output[ch][f_ix] =
	kCompensationGain * final_mask_[f_ix] * input[ch][f_ix];
	}
	}
	}

	NonlinearBeamformer::NonlinearBeamformer(
	const std::vector<Point>& array_geometry,
	size_t num_postfilter_channels,
	SphericalPointf target_direction)
	: num_input_channels_(array_geometry.size()),
	num_postfilter_channels_(num_postfilter_channels),
	array_geometry_(GetCenteredArray(array_geometry)),
	array_normal_(GetArrayNormalIfExists(array_geometry)),
	min_mic_spacing_(GetMinimumSpacing(array_geometry)),
	target_angle_radians_(target_direction.azimuth()),
	away_radians_(std::min(
	static_cast<float>(M_PI),
	std::max(kMinAwayRadians,
	kAwaySlope * static_cast<float>(M_PI) / min_mic_spacing_))) {
	WindowGenerator::KaiserBesselDerived(kKbdAlpha, kFftSize, window_);
	}

	NonlinearBeamformer::~NonlinearBeamformer() = default;

	void NonlinearBeamformer::Initialize(int chunk_size_ms, int sample_rate_hz) {
	chunk_length_ =
	static_cast<size_t>(sample_rate_hz / (1000.f / chunk_size_ms));
	sample_rate_hz_ = sample_rate_hz;

	high_pass_postfilter_mask_ = 1.f;
	is_target_present_ = false;
	hold_target_blocks_ = kHoldTargetSeconds * 2 * sample_rate_hz / kFftSize;
	interference_blocks_count_ = hold_target_blocks_;

	process_transform_.reset(new LappedTransform(num_input_channels_,
	0u,
	chunk_length_,
	window_,
	kFftSize,
	kFftSize / 2,
	this));
	postfilter_transform_.reset(new PostFilterTransform(
	num_postfilter_channels_, chunk_length_, window_, kFftSize));
	const float wave_number_step =
	(2.f * M_PI * sample_rate_hz_) / (kFftSize * kSpeedOfSoundMeterSeconds);
	for (size_t i = 0; i < kNumFreqBins; ++i) {
	time_smooth_mask_[i] = 1.f;
	final_mask_[i] = 1.f;
	wave_numbers_[i] = i * wave_number_step;
	}

	InitLowFrequencyCorrectionRanges();
	InitDiffuseCovMats();
	AimAt(SphericalPointf(target_angle_radians_, 0.f, 1.f));
	}

	// These bin indexes determine the regions over which a mean is taken. This is
	// applied as a constant value over the adjacent end "frequency correction"
	// regions.
	//
	// low_mean_start_bin_ high_mean_start_bin_
	// v v constant
	// \|----------------\|--------\|----------------\|-------\|----------------\|
	// constant ^ ^
	// low_mean_end_bin_ high_mean_end_bin_
	//
	void NonlinearBeamformer::InitLowFrequencyCorrectionRanges() {
	low_mean_start_bin_ = Round(static_cast<float>(kLowMeanStartHz) *
	kFftSize / sample_rate_hz_);
	low_mean_end_bin_ = Round(static_cast<float>(kLowMeanEndHz) *
	kFftSize / sample_rate_hz_);

	RTC_DCHECK_GT(low_mean_start_bin_, 0U);
	RTC_DCHECK_LT(low_mean_start_bin_, low_mean_end_bin_);
	}

	void NonlinearBeamformer::InitHighFrequencyCorrectionRanges() {
	const float kAliasingFreqHz =
	kSpeedOfSoundMeterSeconds /
	(min_mic_spacing_ * (1.f + std::abs(std::cos(target_angle_radians_))));
	const float kHighMeanStartHz = std::min(0.5f * kAliasingFreqHz,
	sample_rate_hz_ / 2.f);
	const float kHighMeanEndHz = std::min(0.75f * kAliasingFreqHz,
	sample_rate_hz_ / 2.f);
	high_mean_start_bin_ = Round(kHighMeanStartHz * kFftSize / sample_rate_hz_);
	high_mean_end_bin_ = Round(kHighMeanEndHz * kFftSize / sample_rate_hz_);

	RTC_DCHECK_LT(low_mean_end_bin_, high_mean_end_bin_);
	RTC_DCHECK_LT(high_mean_start_bin_, high_mean_end_bin_);
	RTC_DCHECK_LT(high_mean_end_bin_, kNumFreqBins - 1);
	}

	void NonlinearBeamformer::InitInterfAngles() {
	interf_angles_radians_.clear();
	const Point target_direction = AzimuthToPoint(target_angle_radians_);
	const Point clockwise_interf_direction =
	AzimuthToPoint(target_angle_radians_ - away_radians_);
	if (!array_normal_ \|\|
	DotProduct(array_normal_, target_direction)
	DotProduct(*array_normal_, clockwise_interf_direction) >=
	0.f) {
	// The target and clockwise interferer are in the same half-plane defined
	// by the array.
	interf_angles_radians_.push_back(target_angle_radians_ - away_radians_);
	} else {
	// Otherwise, the interferer will begin reflecting back at the target.
	// Instead rotate it away 180 degrees.
	interf_angles_radians_.push_back(target_angle_radians_ - away_radians_ +
	M_PI);
	}
	const Point counterclock_interf_direction =
	AzimuthToPoint(target_angle_radians_ + away_radians_);
	if (!array_normal_ \|\|
	DotProduct(array_normal_, target_direction)
	DotProduct(*array_normal_, counterclock_interf_direction) >=
	0.f) {
	// The target and counter-clockwise interferer are in the same half-plane
	// defined by the array.
	interf_angles_radians_.push_back(target_angle_radians_ + away_radians_);
	} else {
	// Otherwise, the interferer will begin reflecting back at the target.
	// Instead rotate it away 180 degrees.
	interf_angles_radians_.push_back(target_angle_radians_ + away_radians_ -
	M_PI);
	}
	}

	void NonlinearBeamformer::InitDelaySumMasks() {
	for (size_t f_ix = 0; f_ix < kNumFreqBins; ++f_ix) {
	delay_sum_masks_[f_ix].Resize(1, num_input_channels_);
	CovarianceMatrixGenerator::PhaseAlignmentMasks(
	f_ix, kFftSize, sample_rate_hz_, kSpeedOfSoundMeterSeconds,
	array_geometry_, target_angle_radians_, &delay_sum_masks_[f_ix]);

	complex_f norm_factor = sqrt(
	ConjugateDotProduct(delay_sum_masks_[f_ix], delay_sum_masks_[f_ix]));
	delay_sum_masks_[f_ix].Scale(1.f / norm_factor);
	}
	}

	void NonlinearBeamformer::InitTargetCovMats() {
	for (size_t i = 0; i < kNumFreqBins; ++i) {
	target_cov_mats_[i].Resize(num_input_channels_, num_input_channels_);
	TransposedConjugatedProduct(delay_sum_masks_[i], &target_cov_mats_[i]);
	}
	}

	void NonlinearBeamformer::InitDiffuseCovMats() {
	for (size_t i = 0; i < kNumFreqBins; ++i) {
	uniform_cov_mat_[i].Resize(num_input_channels_, num_input_channels_);
	CovarianceMatrixGenerator::UniformCovarianceMatrix(
	wave_numbers_[i], array_geometry_, &uniform_cov_mat_[i]);
	complex_f normalization_factor = uniform_cov_mat_[i].elements()[0][0];
	uniform_cov_mat_[i].Scale(1.f / normalization_factor);
	uniform_cov_mat_[i].Scale(1 - kBalance);
	}
	}

	void NonlinearBeamformer::InitInterfCovMats() {
	for (size_t i = 0; i < kNumFreqBins; ++i) {
	interf_cov_mats_[i].clear();
	for (size_t j = 0; j < interf_angles_radians_.size(); ++j) {
	interf_cov_mats_[i].push_back(std::unique_ptr<ComplexMatrixF>(
	new ComplexMatrixF(num_input_channels_, num_input_channels_)));
	ComplexMatrixF angled_cov_mat(num_input_channels_, num_input_channels_);
	CovarianceMatrixGenerator::AngledCovarianceMatrix(
	kSpeedOfSoundMeterSeconds,
	interf_angles_radians_[j],
	i,
	kFftSize,
	kNumFreqBins,
	sample_rate_hz_,
	array_geometry_,
	&angled_cov_mat);
	// Normalize matrices before averaging them.
	complex_f normalization_factor = angled_cov_mat.elements()[0][0];
	angled_cov_mat.Scale(1.f / normalization_factor);
	// Weighted average of matrices.
	angled_cov_mat.Scale(kBalance);
	interf_cov_mats_[i][j]->Add(uniform_cov_mat_[i], angled_cov_mat);
	}
	}
	}

	void NonlinearBeamformer::NormalizeCovMats() {
	for (size_t i = 0; i < kNumFreqBins; ++i) {
	rxiws_[i] = Norm(target_cov_mats_[i], delay_sum_masks_[i]);
	rpsiws_[i].clear();
	for (size_t j = 0; j < interf_angles_radians_.size(); ++j) {
	rpsiws_[i].push_back(Norm(*interf_cov_mats_[i][j], delay_sum_masks_[i]));
	}
	}
	}

	void NonlinearBeamformer::AnalyzeChunk(const ChannelBuffer<float>& data) {
	RTC_DCHECK_EQ(data.num_channels(), num_input_channels_);
	RTC_DCHECK_EQ(data.num_frames_per_band(), chunk_length_);

	old_high_pass_mask_ = high_pass_postfilter_mask_;
	process_transform_->ProcessChunk(data.channels(0), nullptr);
	}

	void NonlinearBeamformer::PostFilter(ChannelBuffer<float>* data) {
	RTC_DCHECK_EQ(data->num_frames_per_band(), chunk_length_);
	// TODO(aluebs): Change to RTC_CHECK_EQ once the ChannelBuffer is updated.
	RTC_DCHECK_GE(data->num_channels(), num_postfilter_channels_);

	postfilter_transform_->ProcessChunk(data->channels(0), final_mask_);

	// Ramp up/down for smoothing is needed in order to avoid discontinuities in
	// the transitions between 10 ms frames.
	const float ramp_increment =
	(high_pass_postfilter_mask_ - old_high_pass_mask_) /
	data->num_frames_per_band();
	for (size_t i = 1; i < data->num_bands(); ++i) {
	float smoothed_mask = old_high_pass_mask_;
	for (size_t j = 0; j < data->num_frames_per_band(); ++j) {
	smoothed_mask += ramp_increment;
	for (size_t k = 0; k < num_postfilter_channels_; ++k) {
	data->channels(i)[k][j] *= smoothed_mask;
	}
	}
	}
	}

	void NonlinearBeamformer::AimAt(const SphericalPointf& target_direction) {
	target_angle_radians_ = target_direction.azimuth();
	InitHighFrequencyCorrectionRanges();
	InitInterfAngles();
	InitDelaySumMasks();
	InitTargetCovMats();
	InitInterfCovMats();
	NormalizeCovMats();
	}

	bool NonlinearBeamformer::IsInBeam(const SphericalPointf& spherical_point) {
	// If more than half-beamwidth degrees away from the beam's center,
	// you are out of the beam.
	return fabs(spherical_point.azimuth() - target_angle_radians_) <
	kHalfBeamWidthRadians;
	}

	bool NonlinearBeamformer::is_target_present() { return is_target_present_; }

	void NonlinearBeamformer::ProcessAudioBlock(const complex_f* const* input,
	size_t num_input_channels,
	size_t num_freq_bins,
	size_t num_output_channels,
	complex_f* const* output) {
	RTC_CHECK_EQ(kNumFreqBins, num_freq_bins);
	RTC_CHECK_EQ(num_input_channels_, num_input_channels);
	RTC_CHECK_EQ(0, num_output_channels);

	// Calculating the post-filter masks. Note that we need two for each
	// frequency bin to account for the positive and negative interferer
	// angle.
	for (size_t i = low_mean_start_bin_; i <= high_mean_end_bin_; ++i) {
	eig_m_.CopyFromColumn(input, i, num_input_channels_);
	float eig_m_norm_factor = std::sqrt(SumSquares(eig_m_));
	if (eig_m_norm_factor != 0.f) {
	eig_m_.Scale(1.f / eig_m_norm_factor);
	}

	float rxim = Norm(target_cov_mats_[i], eig_m_);
	float ratio_rxiw_rxim = 0.f;
	if (rxim > 0.f) {
	ratio_rxiw_rxim = rxiws_[i] / rxim;
	}

	complex_f rmw = abs(ConjugateDotProduct(delay_sum_masks_[i], eig_m_));
	rmw *= rmw;
	float rmw_r = rmw.real();

	new_mask_[i] = CalculatePostfilterMask(*interf_cov_mats_[i][0],
	rpsiws_[i][0],
	ratio_rxiw_rxim,
	rmw_r);
	for (size_t j = 1; j < interf_angles_radians_.size(); ++j) {
	float tmp_mask = CalculatePostfilterMask(*interf_cov_mats_[i][j],
	rpsiws_[i][j],
	ratio_rxiw_rxim,
	rmw_r);
	if (tmp_mask < new_mask_[i]) {
	new_mask_[i] = tmp_mask;
	}
	}
	}

	ApplyMaskTimeSmoothing();
	EstimateTargetPresence();
	ApplyLowFrequencyCorrection();
	ApplyHighFrequencyCorrection();
	ApplyMaskFrequencySmoothing();
	}

	float NonlinearBeamformer::CalculatePostfilterMask(
	const ComplexMatrixF& interf_cov_mat,
	float rpsiw,
	float ratio_rxiw_rxim,
	float rmw_r) {
	float rpsim = Norm(interf_cov_mat, eig_m_);

	float ratio = 0.f;
	if (rpsim > 0.f) {
	ratio = rpsiw / rpsim;
	}

	float numerator = 1.f - kCutOffConstant;
	if (rmw_r > 0.f) {
	numerator = 1.f - std::min(kCutOffConstant, ratio / rmw_r);
	}

	float denominator = 1.f - kCutOffConstant;
	if (ratio_rxiw_rxim > 0.f) {
	denominator = 1.f - std::min(kCutOffConstant, ratio / ratio_rxiw_rxim);
	}

	return numerator / denominator;
	}

	// Smooth new_mask_ into time_smooth_mask_.
	void NonlinearBeamformer::ApplyMaskTimeSmoothing() {
	for (size_t i = low_mean_start_bin_; i <= high_mean_end_bin_; ++i) {
	time_smooth_mask_[i] = kMaskTimeSmoothAlpha * new_mask_[i] +
	(1 - kMaskTimeSmoothAlpha) * time_smooth_mask_[i];
	}
	}

	// Copy time_smooth_mask_ to final_mask_ and smooth over frequency.
	void NonlinearBeamformer::ApplyMaskFrequencySmoothing() {
	// Smooth over frequency in both directions. The "frequency correction"
	// regions have constant value, but we enter them to smooth over the jump
	// that exists at the boundary. However, this does mean when smoothing "away"
	// from the region that we only need to use the last element.
	//
	// Upward smoothing:
	// low_mean_start_bin_
	// v
	// \|------\|------------\|------\|
	// ^------------------>^
	//
	// Downward smoothing:
	// high_mean_end_bin_
	// v
	// \|------\|------------\|------\|
	// ^<------------------^
	std::copy(time_smooth_mask_, time_smooth_mask_ + kNumFreqBins, final_mask_);
	for (size_t i = low_mean_start_bin_; i < kNumFreqBins; ++i) {
	final_mask_[i] = kMaskFrequencySmoothAlpha * final_mask_[i] +
	(1 - kMaskFrequencySmoothAlpha) * final_mask_[i - 1];
	}
	for (size_t i = high_mean_end_bin_ + 1; i > 0; --i) {
	final_mask_[i - 1] = kMaskFrequencySmoothAlpha * final_mask_[i - 1] +
	(1 - kMaskFrequencySmoothAlpha) * final_mask_[i];
	}
	}

	// Apply low frequency correction to time_smooth_mask_.
	void NonlinearBeamformer::ApplyLowFrequencyCorrection() {
	const float low_frequency_mask =
	MaskRangeMean(low_mean_start_bin_, low_mean_end_bin_ + 1);
	std::fill(time_smooth_mask_, time_smooth_mask_ + low_mean_start_bin_,
	low_frequency_mask);
	}

	// Apply high frequency correction to time_smooth_mask_. Update
	// high_pass_postfilter_mask_ to use for the high frequency time-domain bands.
	void NonlinearBeamformer::ApplyHighFrequencyCorrection() {
	high_pass_postfilter_mask_ =
	MaskRangeMean(high_mean_start_bin_, high_mean_end_bin_ + 1);
	std::fill(time_smooth_mask_ + high_mean_end_bin_ + 1,
	time_smooth_mask_ + kNumFreqBins, high_pass_postfilter_mask_);
	}

	// Compute mean over the given range of time_smooth_mask_, [first, last).
	float NonlinearBeamformer::MaskRangeMean(size_t first, size_t last) {
	RTC_DCHECK_GT(last, first);
	const float sum = std::accumulate(time_smooth_mask_ + first,
	time_smooth_mask_ + last, 0.f);
	return sum / (last - first);
	}

	void NonlinearBeamformer::EstimateTargetPresence() {
	const size_t quantile = static_cast<size_t>(
	(high_mean_end_bin_ - low_mean_start_bin_) * kMaskQuantile +
	low_mean_start_bin_);
	std::nth_element(new_mask_ + low_mean_start_bin_, new_mask_ + quantile,
	new_mask_ + high_mean_end_bin_ + 1);
	if (new_mask_[quantile] > kMaskTargetThreshold) {
	is_target_present_ = true;
	interference_blocks_count_ = 0;
	} else {
	is_target_present_ = interference_blocks_count_++ < hold_target_blocks_;
	}
	}

	} // namespace webrtc